BRPI0804351B1 - device and method for discharging granular material - Google Patents

Abstract

device and method for discharging granular material. The invention relates to a device (1) for discharging granular material, with a receptacle (2) into which the granular material may be introduced, with a separation grid (4) which is disposed in the receptacle (2), and a intermediate plate (6) which is arranged below the separation grid (4), wherein the intermediate plate (6) is equipped with a through opening (5) for the granular material, and with an opening which is provided below the intermediate plate (6) and through which the granular material can be removed from the receptacle (2). According to the invention, the intermediate plate (6) is arranged to be rotatable with respect to the separation grid (4) and the separation grid (4) is arranged to be stationary with respect to the receptacle (2).

Description

"DEVICE AND METHOD FOR DOWNLOADING GRANULAR MATERIAL" The present invention relates to a device for discharging granular material. As part of the recycling processes for plastic bottles, and in particular for PET bottles, it is customary to comminute these bottles and subsequently clean the individual comminuted pieces or flakes in order to subsequently send them for recycling. With some methods, it is necessary as part of this recycling process to remove granular material from a receptacle. During this removal of the granular material, the problem of agglomeration of the granular material, or the joint wedging of some particles of this granular material, often arises. It is therefore an object of the present invention to make available a discharge base which is suitable even for granular material subject to agglomeration. The invention is described with reference to PET flakes from a recycling process, but it is emphasized that the invention is also suitable for other types of granular material.

A device for discharging granular material according to the invention is equipped with a receptacle into which granular material may be introduced. Further there is provided a separation grid which is disposed in the receptacle and an intermediate plate which is arranged below this separation grid wherein the intermediate plate is equipped with at least one through opening for the granular material. Still provided below the intermediate plate is an opening through which granular material can be removed from the receptacle. According to the invention, the intermediate plate is arranged to be rotatable with respect to the separation grid and the separation grid is arranged to be that in relation to the receptacle.

By means of the separation grid, the region above the intermediate plate is divided into a plurality of segments, and by rotating the intermediate plate, the granular material is then allowed to fall through the through opening in the intermediate plate. Due to the segmentation of the surface above the intermediate plate, agglomeration of the granular material is prevented. The receptacle is preferably equipped with a flange installation so that it can be flangedly connected to silos, storage tanks, reaction tanks, or the like. To be more precise, the entire device is preferably flanged to the bottom of silos, storage tanks, reaction tanks or the like, wherein these silos may be of a cylindrical, conical bottom, conical roof or polygonal design. The device thus comprises a dual chamber system, wherein one chamber is disposed above the intermediate plate, and the other chamber is disposed below the intermediate plate. The upper region, that is, the region above the middle plate, serves as a storage chamber and also contains the stationary separation grid (also called the discharge grid). Located under the middle plate is the discharge chamber. From this region, the granular material is discharged from the device and thus from the silo, and preferably sent to an additional unit or other conveyor systems, such as conveyor belts or trucks. To be more precise, the opening provided below the intermediate plate serves to discharge the granular material.

In an advantageous embodiment, a base plate that is stationary with respect to the receptacle is provided below the intermediate plate, and the opening is arranged in this base plate. In operation, the granular material may thus fall through the through opening in the intermediate plate and over the base plate.

Preferably provided above the base plate for this purpose is a displacement apparatus which is rotatable with respect to the receptacle and which moves the granular material with respect to the base plate. To be more precise, in this discharge chamber, that is, the region above the baseplate, the granular material is discharged via the opening or tubing by means of a rotary scraper.

By this embodiment, the discharge base according to the invention is suitable for granular material of all types. Even problematic granular material with a tendency to bind can be discharged more evenly by this discharge means. The displacement apparatus is preferably equipped with a curvature in conjunction with an opening aperture cross section in the base plate. This is to be interpreted as meaning that the displacement apparatus or scraper is bent in such a way that the granular material is forced into the particular radial region of the base plate in which the opening is also situated. To be more precise, by movement of the displacement apparatus, the granular material is forced into a region of the displacement apparatus that forms a recess in the direction of rotation. Also provided in this region is the opening in the baseplate. Depending on the application, however, the scraper may also be straight or may have a negative curvature. The through opening is preferably a slot extending in a radial direction of the intermediate plate. In a further advantageous embodiment, a plurality of such slots may also be provided. The provision of these slots enables extremely uniform discharge of granular material. The through aperture preferably extends essentially along essentially the entire radial length of the intermediate plate, so that the granular material may pass through the intermediate plate throughout the radial region. For added stability, ears joining the edges of the slots may also be provided. In the event that a plurality of such openings in the form of slots are provided, it is especially preferred if they are essentially evenly distributed with respect to one another. the other in the peripheral direction.

Prior to the through opening in the direction of rotation, the intermediate plate is equipped, in the case of an additional advantageous embodiment, with an oblique surface which preferably hides the through opening located below this oblique surface. As already mentioned, the swivel intermediate plate can be equipped with one or more discharge slots. In this way, direct sliding of the granular material through the intermediate plate is prevented, and during rotation of the intermediate plate, this oblique surface serves to compact the granular material just before the oblique surface or ramp, so that compressed material in this manner is relieved. in pressure after the ramp and falls through the intermediate plate into the discharge chamber. The oblique surface or ramp is preferably inclined between 20 ° and 30 ° with respect to the plane of the intermediate plate. The amount and shape of these discharge slots or through openings are conjugated to the granular material, and closely related to the overall base area of the device. The separation grid thus preferably comprises surfaces installed in a perpendicular alignment, i.e. panels located perpendicular to the intermediate plate, together with the discharge base disposed below. The device is preferably equipped with a drive device that drives the intermediate plate, and this drive device is provided below the receptacle. Depending on the sealing materials, high process temperatures of up to 260 ° to 300 ° can thus be achieved. With this embodiment, applications regarding either vacuum or positive pressure are conceivable. The mid-plate rotates at a speed between 1 rpm and 10 rpm, preferably between 1 rpm and 7 rpm and - especially for industrial scale applications - between 1 rpm and 3 rpm. The drive motor is preferably frequency regulated.

In the case of an additional advantageous embodiment, the separation grid is equipped with between three and twelve arms, between four and ten being preferred and between four and eight being especially preferred these arms extending in the radial direction of the intermediate plate. These radially arranged perpendicular arms or panels preferably taper towards the top to prevent any agglomeration. The smaller the number of these arms or panels, the greater the tendency for reverse mixing of granular material. The greater the amount of these arms or panels, however, the greater the risk of crowding in the device. The spacing of these arms is thus preferably conjugated to the granular material, and in this way any mastication or pulping of the granular material or co-rotation thereof is prevented, thereby preserving the product. It is also possible to arrange the arms obliquely with respect to the intermediate plate. The separation grid is preferably arranged at a distance from the intermediate plate. Emptying of the intermediate plate thus occurs by scraping, and in this way the core flow is minimized. It is also possible to provide for the removal of granular material from the receptacle by the first-in-first-out principle. Use for all types of time-controlled processes in reactors is also conceivable. The distance between the arms and the intermediate plate is preferably between 10 mm and 20 mm.

In the case of an additional advantageous embodiment, the device is equipped with a conical dispensing element which is centrally arranged above the intermediate plate. It is especially preferred that this conical element is arranged such that its symmetry axis coincides with the symmetry axis of the intermediate plate. This cone enables virtually complete emptying of the silo which is advantageous in particular in processes where product changes are required. This conical element preferably rotates together with the intermediate plate. The storage chamber which is formed above the intermediate plate thus comprises a tube which is preferably cylindrical, the aforesaid separation grid, the aforementioned conical element and the rotating intermediate plate. The present invention is further directed to a method for discharging granular material from a receptacle, wherein in a first step the granular material is introduced into the receptacle, for example from a silo, and more precisely the granular material is introduced from above onto an intermediate plate that rotates relative to a separation grid that is arranged above the intermediate plate. The granular material is then loaded through at least one predicted opening in the intermediate plate. The granular material is then discharged from the receptacle through an opening provided below the intermediate plate. According to the invention, the separation grid is stationary relative to the receptacle, and the intermediate plate moves relative to the receptacle, and in particular the intermediate plate rotates relative to the receptacle.

Below the intermediate plate, the granular material preferably falls onto a base plate.

In the case of a further preferred method, using a displacement apparatus, the granular material is displaced relative to the base plate and by this displacement is finally discharged from the device.

Additional advantages and embodiments may be derived from the accompanying drawings.

In the drawings: Fig. 1 shows a first partially sectional view of a device according to the invention. Fig. 2 shows a cross-sectional view of the device shown in fig. 1. Fig. 3 shows an additional perspective view of the device shown in fig. 1. Fig. 1 shows a perspective view of a device 1 according to the invention. This device is equipped with a receptacle 2 which may be flanged by means of a flange 26 in a silo (not shown), for example on an underside of this silo.

Provided within the receptacle 2 is a separation grid, designated in its entirety as 4, which, in the version shown in FIG. 1 is equipped with four arms (or perpendicular panels) 8 extending in a radial direction. This separation grid is arranged to be stationary relative to the receptacle 2. Reference numeral 13 refers to a funnel-shaped edge which, together with the separation grid 4, is also arranged to be stationary. Provided below the grid separation 4 is an intermediate plate 6 which is arranged to be rotatable within the receptacle 2. The separation grid 4 is arranged such that the individual arms do not directly contact the intermediate plate 6, but are arranged slightly above. of the intermediate plate.

In this way the unloading of the granular material may take place in a "scraping manner". Provided in the intermediate plate 6 is a through opening 5 in the form of a slot extending in the radial direction. The intermediate plate 6 is further equipped with an oblique surface 9 which conceals the through opening 5 located below in the perpendicular direction L. This oblique surface is located before the through opening in the direction of rotation of the intermediate plate. In the case of the embodiment shown in fig. 1, the intermediate plate 6 then rotates counterclockwise. The intermediate plate 6 is driven by a motor 20 via a spindle 24.

Provided below the intermediate plate is a base plate 12 which is also arranged to be stationary. This base plate 12, which is preferably made of high quality steel, is equipped with an opening (not shown in fig. 1) through which the granular material can be discharged through a discharge tube 7. Still provided between the intermediate plate 6 and base plate 12, and disposed above base plate 12 is a displacement apparatus which moves granular material which has fallen through the through opening 5 relative to base plate 12 until it can exit through the exit opening provided in the base plate 12. The space below the intermediate plate 6 thus forms a loading chamber 30 for the granular material, and the space above the intermediate plate 6 forms a storage chamber 28. Device 1 is sized here as such. whereby the storage chamber 28 has a larger chamber than the discharge chamber 30 disposed below the intermediate plate 6. FIG. 2 shows a cross-sectional view of the device shown in FIG. 1. It can be seen here that disposed above the intermediate plate 6 is a conical element 22 which here rotates together with the intermediate plate 6 and enables the complete emptying of the silo. Still provided between the intermediate plate 6 and the base plate 12 is a drive sleeve 21 and brackets 25, which rotatably support the intermediate plate 12. In the case of the method according to the invention, it is for example possible to introduce batches with a predetermined weight on the discharge base or within the receptacle. In the radial direction, the through opening 5 has a width between 3 mm and 20 mm, between 5 mm and 16 mm being preferred and between 6 mm and 12 mm being especially preferred. The amount of arms 8 to be selected depends among other things on the nature of the specific granular material. The advantage of fewer arms, for example the four arms 8 shown in fig. 1, lies in the fact that less granular material or less flakes will be placed on the grid or the arms themselves 8, and also that fewer components are needed. However, the risk of reverse mixing is increased in this case. Providing more arms 8 reduces the risk of reverse mixing but the cost is increased by the required parts.

Because of the geometry of the discharge organ, any restriction on uniform, perpendicular mobility of granular material in the silo may be counteracted. The storage chamber 28 provided above the intermediate plate 6 is separated from the discharge chamber provided below the intermediate plate 6 by means of a sealing device, a labyrinth seal being especially preferred. Any direct through fall of granular material outside the through aperture 5 is prevented by this seal. As already mentioned, the funnel-shaped region or rim 13 serves to deflect the granular material and thus to prevent agglomeration. Fig. 3 shows a further view of a device according to the invention. Seen here is the displacement apparatus 14 which is disposed below the intermediate plate 6 but above the base plate 12. This displacement apparatus constantly rotates relative to the base plate 12. The rotary movement of this displacement apparatus 14 is preferably synchronized or coupled with the rotary movement of the intermediate plate 6.

By means of this displacement apparatus 14, the falling granular material passing over the base plate 12 is offset relative to the base plate 12 and is finally forced into an outlet opening (not shown) through which it can fall. In the case of the embodiment shown in fig. 3, this outlet opening is provided downstream of the displacement apparatus 14. This outlet opening preferably has a circular profile. The displacement apparatus 14 is also at least slightly spaced from the base plate 12. However, it would also be possible to provide more than one such displacement apparatus. It can be seen that the displacement apparatus has a curvature 14a which is of a design such that during counterclockwise rotation of the displacement apparatus 14, the granular material is forced into this curvature. At a preset rotation position of the displacement apparatus, the opening in the base plate 12 s lies just below this curvature. In this way, an especially efficient discharge of granular material through the base plate 12 is achieved.

To be more precise, this curvature 14a is combined with the opening cross section of the discharge opening, and the aforementioned displacement or scraper spacing is again here dependent on the granular material. This spacing is preferably adjustable relative to the baseplate. In this way any mastication or pulping of the granular material is prevented, thus conserving the product. In order to achieve complete emptying of the device, additional enhancement methods could also be implemented. For example, a rotating brush could be provided above the intermediate plate 6. It would also be possible to provide rubber blades on the intermediate plate which also enables complete emptying. It would also be possible to achieve complete emptying through a fan either above the intermediate plate or under the intermediate plate. It would also be possible to achieve complete emptying by electrostatic charging of the individual flakes. All the features described in the application application documents are claimed as essential to the invention to the extent that, either individually or in combination, they are new to the prior art.

Claims (13)

1. Device (1) for discharging granular material, with a receptacle (2) into which the granular material may be introduced, with a separation grid (4) which is disposed in the receptacle (2), and an intermediate plate ( 6) which is disposed below the separation grid (4), wherein the intermediate plate (6) is equipped with a through opening (5) for the granular material, and with an opening that is provided below the intermediate plate (6). 6) and through which the granular material can be removed from the receptacle (2), characterized in that the intermediate plate (6) is arranged to be rotatable with respect to the separation grid (4) and the separation grid (4). ) is arranged to be stationary relative to the receptacle (2). Device (1) according to claim 1, characterized in that a base plate (12) which is stationary relative to the receptacle (2) is provided below the intermediate plate (6), and the opening (8) is arranged on this base plate (12). Device (1) according to claim 2, characterized in that a displacement apparatus (14) is provided above the base plate (12) which is rotatable with respect to the receptacle (2) and which moves the granular material relative to the base plate (12). Device (1) according to Claim 3, characterized in that the displacement apparatus (14) is equipped with a curvature (14a) in conjunction with the opening aperture cross-section. Device (1) according to at least one of the preceding claims, characterized in that the through opening (5) is a slot extending in a radial direction of the intermediate plate (6). Device (1) according to at least one of the preceding claims, characterized in that, prior to the through-opening (5) in the direction of rotation, the intermediate plate (4) is provided with an oblique surface (9) which protects it. it conceals the through opening (5) located below this oblique surface (9). Device (1) according to at least one of the preceding claims, characterized in that it is equipped with a drive device which drives the intermediate plate (6), and wherein this drive device (20) is provided below. receptacle (2). Device (1) according to at least one of the preceding claims, characterized in that the separation grid is equipped with between 3 and 12 arms (8), between 4 and 10 being preferred and between 4 and 8 being especially Preferred are arms (8) extending in a radial direction from the intermediate plate (6). Device (1) according to at least one of the preceding claims, characterized in that the separation grid (4) is arranged at a distance from the intermediate plate (6). Device (1) according to at least one of the preceding claims, characterized in that it is equipped with a conical distributing element (22) which is centrally arranged above the intermediate plate (6). 11. Method for discharging granular material from a receptacle (2) with the following steps: - introducing granular material into the receptacle (2), wherein the granular material is introduced from above onto an intermediate plate (6) which rotates in relation to a separation grid (4) which is disposed on the intermediate plate (6); - driving the granular material through at least one opening (5) provided in the intermediate plate (6); unloading the granular material from the receptacle (2) through an opening provided below the intermediate plate (6), characterized in that the separation grid (2) is stationary with respect to the receptacle (2), and intermediate plate (6) moves relative to the receptacle (2). Method according to claim 11, characterized in that below the intermediate plate (6), the granular material falls onto a base plate (12). A method according to claim 12, characterized in that the granular material is displaced with respect to the base plate (12) by means of a displacement apparatus (14).